Apparatus for obtaining differential tangential variable speeds at different points of a deformable film

ABSTRACT

The invention relates to a drawing device. This device is designed such that the differential tangential speeds V are variable at different points of a deformable flat film (1) or plate that moves along at least one drawing roller (3) rotating about an axis XX, said film (1) or plate moving in a direction perpendicular to the axis of rotation of the roller and resting on a generatrix G N  of the roller. The roller (3) has a rotational speed N which is constant with time, while the distance G N  C 1  from the supporting generatrix G N  of the film to the axis C 1  of rotation of the roller is variable with time. The invention is applicable to the drawing of plastic films.

This application is a continuation of U.S. Pat. application Ser. No. 372,103, filed Jun. 28, 1989, now abandoned, which is a continuation of U.S. patent application Ser. No. 062,315, filed Jun. 8, 1987, now abandoned, which is a divisional of U.S. patent application Ser. No. 546,034, filed Oct. 27, 1983, now U.S. Pat. No. 4,606,098.

The invention relates to an apparatus for obtaining differential variable speeds at various points of a flat film which is more particularly elastically or plastically deformable.

In numerous industries, particularly in the textile and metallurigical industries, it is common practice and necessary to draw flat stock with the object of thinning down or calendering these products. Sometimes it is necessary to prestress plastic, metallurgical or textile products. Finally, in the packing industry, plastic films are drawn prior to placing them around palletized loads and causing them to retract naturally or not.

In general, to carry out these operations, it is necessary to obtain different speeds between two different points of the film. To do this, it is common practice to use two rollers turning about parallel axes at different rotational speeds. Thus, in general, the rotational speed of the downstream roller is higher than that of the upstream roller. In particular, the angular speeds of the rotating rollers are varied by mechanical, electronic, hydraulic means and by gear boxes, gearings, etc. However, the devices of the prior art do not permit variation of the differential speed ratio by a value very much higher than 1, e.g., up to 3. Moreover, when banderoling pallets in the starting phase, it is not possible to obtain a differential speed ratio equal to 1 without using coupling devices.

The primary object of the invention is to overcome these drawbacks.

The invention relates to an apparatus for obtaining differential tangential variable speeds at different points of a deformable flat film or plate moving along at least one drawing roller rotating about an axis, said film or plate moving in a direction perpendicular to the axis of rotation of the roller and resting on a generatrix of the drawing roller.

This apparatus is characterized by the fact that the roller has a rotational speed which is constant with time, whereas the distance from the supporting generatrix of the film to the axis of rotation of the roller is variable with time.

According to a first embodiment of the invention, the drawing roller is formed by a plurality of contiguous generatrices whose distance to the axis of rotation increases continuously with time from the downstream generatrix from which issues the drawn film.

According to a second embodiment, the drawing roller is a deformable cylinder, in particular a cylinder of revolution having an axis of rotation which is displaced in relation to the axis of revolution, the distance between the contiguous generatrices increasing continuously with time from the upstream generatrix reached by the undrawn film to the downstream generatrix from which issues the drawn film.

The film rests on the generatrix by means of at least one pressure member that exerts pressure on the roller, in particular a supporting roller, said member moving as it rotates about its axis dependent upon the displacement of the supporting generatrix, and the film being placed between the supporting member and the roller.

The ratio of the initial distance R₀ from the upstream generatrix to the axis of rotation to the final distance R₁ from the downstream generatrix to the axis of rotation is adjustable.

Finally, according to a third embodiment, the film is carried along by the rotation of two circular-cylinder rollers having a circular base and parallel axes of rotation, the upstream radius R₀ and the downstream radius R₁ being variable with time. Furthermore, the drawing ratio, more particularly the ratio of the differential tangential speed V₁ at a point of the film downstream, following drawing, to the differential tangential speed V₀ at a point of the film upstream, prior to drawing, is proportional to the ratio of the radius R₁ of the downstream roller to the radius R₀ of the upstream roller.

It will be understood that the apparatus embodying the principles of the invention has significant advantages over devices of the prior art. Indeed, it is easy to adjust the drawing either by changing the position of the axis of rotation relative to the axis of revolution; this modifies the distance between the generatrix on which the film rests and the axis of rotation of the roller, or by modifying the radii of the rollers relative to one another. In addition, several rollers, as required, can be utilized which, by varying their radii, enables one to obtain differential variable speeds.

For a more complete understanding of the present invention, reference is now made to the following description of illustrative embodiments presented hereinbelow in connection with the accompanying drawings, in which:

FIG. 1 is a schematic view of a first embodiment of the invention;

FIG. 2 is a schematic view of a second embodiment;

FIG. 3 is a perspective view of a third embodiment;

FIGS. 4A and 4B show the variation of the radii of the rollers for, respectively, minimum drawing and maximum drawing.

FIG. 5 shows a first embodiment of a roller;

FIG. 6 shows a second embodiment of a roller;

FIG. 7A and 7B show a first variation of the third embodiment with minimum drawing (7A) and maximum drawing (7B);

FIGS. 7C and 7D are top plan views of, on one side, a portion of the rollers and, on the other side, the means controlling the expansion or the contraction of the rollers.

FIGS. 8A and 8B illustrate a second variation of this last embodiment of the invention with, respectively, minimum drawing and maximum drawing.

FIG. 9 is a side view of another variation of the roller of the invention;

FIG. 10 is an enlarged view of a detail of the roller of FIG. 9;

FIG. 11 is a side view of another variation similar to that depicted in FIG. 9;

FIG. 12 is a schematic view of the operation of an apparatus of the invention equipped with rollers such as the roller of FIG. 11.

The apparatus of the invention enables one to obtain differential tangential variable speeds at different points of a deformable flat film or plate, more particularly an elastically or plastically deformable film. It is well known that elastic deformation is reversible and that the film, when no longer drawn, resumes its initial position, whereas plastic deformation is partly irreversible and the film, when no longer drawn, has a final length which is greater than its initial length.

Tangential differential speed is the speed of the film moving along at least one roller or carried along by the rotation of at least one roller rotating about its axis, the film moving in a direction perpendicular to the axis of rotation of the roller and resting on a generatrix of the roller.

According to the invention, the roller has a speed of rotation N which is constant with time, while the distance R from the supporting generatrix or surface section for the film to the axis of rotation of the roller is variable with time.

FIG. 1 depicts a first embodiment of the invention. A film 1 arrives upstream in drawing apparatus 2 and issues downstream therefrom. Since the tangential speed of film 1 upstream is V₀, the tangential speed of film 1 downstream equals V_(N). Apparatus 2 enables one to obtain tangential differential speeds V_(N), which are variable at different points of film 1. The latter is flat and in FIG. 1 it is shown perpendicular to the plane of the figure. It is a film which is elastically or plastically deformable and is preferably made from synthetic material. The length L₀ between two points AB of the film upstream is less than the length L_(N) between the same points AB of film 1 downstream.

According to the invention, apparatus 2 permits the drawing of film 1, i.e., the segment AB with a length L that gradually attains the length L_(N) (FIG. 1).

This first embodiment comprises a roller 3 formed by a plurality of contiguous generatrices G₀, . . . G_(N). Generatrices G are caused to rotate about an axis C by a drive mechanism 4, preferably at least two spiders formed by flat circular sections placed at each end of generatrices G_(N). The center of rotation C₁, through which passes the axis of rotation of the spider, is displaced in relation to the center of rotation C of drawing roller 3 by a distance. The direction of rotation of drive mechanism 4 is the same as that of drawing roller 3. Film 1 is carried along by the rotation of at least one roller 3 turning about an axis of rotation C, at right angles to the plane of the figure. Film 1 moves in a direction perpendicular to the axis of rotation of drawing roller 3 and rests on a generatrix G_(N) of roller 3 at instant t_(N) ₁. Thus, at instant t₀, film 1 bears on generatrix G₀, its speed is V₀, at instant t₁ =t₀ +Δt, film 1 rests on generatrix G₁, its speed is V₁ =V₀ +αV₀, at instant t_(N) the film rests on generatrix G_(N), its speed V_(N) =V+ΣΔV_(N-1). Preferably the speed increments ΔV_(N-1) are constant, but they may also vary. Drawing roller 3 rotates in the direction of arrow F₁ and has an angular speed of rotation N which is constant with time, while the distance from supporting generatrix G_(N) to the axis of rotation of the drawing roller C, or center of rotation of the spiders 4, varies. Preferably, the distances C₁ G₀. . . C₁ G_(N) are such that C₁ G₀ <. . . <C₁ G_(N) and the distance from the axis of rotation C₁ of drive mechanism 4 to generatrix G₀ downstream is less than the distance from the axis of rotation to generatrix G_(N) downstream. This distance G_(N) C₁ increases continuously during the interval from upstream to downstream. The initial distance G₀ C₁ upstream equals r, while the final down stream distance equals R.

The distance e from the center of rotation C of drawing roller 3 to the center of rotation C₁ of drive mechanism 4 is adjustable; this permits adjustment of the final tangential speed V_(N) in relation to the initial tangential speed V₀ and, thereby, the adjustment of the drawing ratio V_(n) /V₀.

This drawing ratio can increase up to 2 or 3, at any rate it is much higher than 1 and can also be adjusted to be less than 1.

The drawing ratio can be made such as to equal 1 when drawing a plastic film that is utilized for the banderoling of pallets. This drawing ratio equalling 1 is necessary at the start of the banderoling, since the film shall not be drawn. In this case, the distance CC₁, zero. Thus, by displacing the center C in relation to the center C₁ the invention makes it possible to gradually adjust the drawing ratio.

According to a second embodiment of the apparatus of the invention (FIG. 2), the drawing roller is a cylinder of revolution 5, preferably having a circular base, whose axis of rotation of the center C₂ is displaced relative to the axis of revolution of the center C₃. The drawing cylinder is deformable and is preferably made from elastomeric material. Thus, the distance between the contiguous generatrices G₀, G₁, . . . G_(N) increases continuously during the rotation (direction of arrow F₂) when the center of rotation C₂ is displaced on the upstream side in relation to the center of revolution C₃.

Film 1 rests on generatrix G_(N) at an instant t_(N) and a loose pulley 6 causes the deformation of deformable supporting cylinder 5 which moves as it rotates about the center C₃. The film is introduced upstream on the side where the distance r=C₂ G₀ from the center of rotation C₂ to the generatrix G₀ is the shortest, and issues downstream on the side where the distance R=C₂ G_(N) from the center of rotation C₂ to generatrix G_(N) is the longest.

By adjusting the distance C₂ C₃ with the aid of pulley 6, the drawing ratio (V_(n) /V₀), which may equal 1 when C₂ merges with C₃, is adjusted.

According to a third embodiment of the invention (FIGS. 3-8), the film moves along two circular-cylindrical rollers 7, 8 having a circular base and parallel rotating axles XX, YY, the radius R₀ of upstream cylinder 7 and the radius R₁ of downstream cylinder 8 being variable with time. Film 1 moves in a direction perpendicular to axles XX, YY.

According to the invention, tangential speed V₀ of film 1 upstream is different from the tangential speed V₁ of film 1 downstream.

Film 1, moving at speed V₁, can drive the set of rollers 7 and 8. In a variation, film 1 is driven at speed V₁ by the roller 8 driven by a motor 9.

According to the invention, rollers 7, 8 are rotated in such a way that the ratio K of the speed of rotation N₁ of cylinder 8 to the speed of rotation N₀ of cylinder 7 is constant. They have opposed directions of rotation, cylinder 7 working in the direction of arrow F3 and cylinder 8 rotating in the opposite direction (arrow F4).

Therefore, if E is the drawing ratio of the film, L₁ is the length of a segment AB downstream, and L₀ is the length of the segment AB of film 1 upstream, the following equation is valid: ##EQU1##

At instant t, one has L₀ =V₀ t and L₁ =V₁ t. Therefore, ##EQU2##

However, the tangential speed equals the radius of the cylinder multiplied by the speed of rotation of the cylinder.

Therefore, ##EQU3##

According to the invention, ##EQU4##

By varying the radii R₀ and R₁ of upstream cylinder 7 and of downstream cylinder 8, one varies the ratio of the tangential speeds V₀ and V₁.

The distance from a generatrix G_(N) to centers of rotation C₀ and C₁ thus varies with time, since radii R₀ and R₁ are variable.

If R₀ and R₁ vary between the limit values r and R, when R₁ =r and R₀ =R, the drawing ratio E is at a minimum (FIG. 4A), whereas, if R₁ =R and R₀ =r. the drawing ratio E is at a maximum (FIG. 4B).

Thus, ##EQU5##

If it is desired to vary the drawing ratio from 0 to 100%, then ##EQU6##

The average radius is ±97 mm.

If it is desired to vary the drawing from 0 to 200%, then ##EQU7##

The average radius is ±97 mm.

If a drawing ratio E equal to 1 is desired, K (n₁ /n₀) must in the first case equal ±1.4, and in the second case it must equal ±1.7. The ratios K of the speeds of rotation are adjusted by means of a gearing 10.

According to an embodiment of the invention illustrated in FIGS. 7A, 7B, 7C and 7D, the apparatus for the variable predrawing or drawing comprises two drawing rollers 7 and 8 consisting of a plurality of longitudinal curved portions 11 forming the cylindrical surface of the roller. The two rotating axles XX, YY of the rollers are parallel oriented in a relationship to each other.

The function of guide members 12 for guiding curved portions 11 of rotating axles XX and YY into radial translation is to move them away or bring them closer together. The function of drive mechanisms 13 for rotating the curved portions 11 is to pivot them about axles XX and YY and, finally, the function of control units 14 is to activate guide members 12.

Preferably, the drive mechanisms 13 for rotating the curve portions 11 consist of hubs 15 which enable the latter to rotate about axles XX or YY, which are fluted axles. These fluted axles pivot on bearings 16.

Guide members 12 for guiding the curved portions 11 in such a way as to slide in radial translation consist of ramps 17 which rest in grooves 18 provided in hubs 15. Each drawing roller 11 has at least two hubs 15. Hubs 15 of a cylinder 7 slide simultaneously along a respective fluted axle XX or YY.

Ramps 17 are capable of sliding radially in grooves 18. Thus, the radius of drawing rollers 7 and 8 can vary by sliding ramps 17 radially in grooves 18 and, simultaneously, by sliding hubs 15 in an axial direction.

Each cylindrical roller 7, 8 has at least one flange 19 to ensure the end guidance of portions 11. Stops 20 can slide radially in relation to the respective flanges 19.

The apparatus also includes control units 14 to activate the guide members 12 for causing portions 11 to slide in radial and axial translation. Control units 14 consist of a double fork 21 pivoting about an axis 22, which is oriented perpendicular to rotating axles XX, YY of rollers 7, 8. Double fork 21 acts by means of supporting rims 23, each being mounted to one end of a respective rotating axles XX, YY of the rollers. Each supporting rim 23' is mounted to the respective axle XX or YY by a thrust ball bearing 23.

Thus, when double fork 21 leans on the side of upstream roller 7 (FIG. 7A), it acts on stop 23, causing hubs 15 of upstream roller 7 to slide axially. Hubs 15 are displaced to the end of axle XX which does not have the stop 23. Hubs 15, as they move, compress a return spring 24 mounted over the axle XX. Portions 11 and ramps 17 lie flat on the sliding hubs 15 and are supported by circumferential springs 25 located on each level of the ramps 17.

Hubs 15, as they move along axle XX, push portions 11 radially outwardly, thus ensuring the increase of the radius of roller 7, which assumes the value R.

By contrast, fork 21 is connected at its other end on the side of downstream roller 8, wherein the hubs 15 are in a position opposite to the hubs 15 of upstream roller 7. Return spring 24 urges the sliding hubs 15 and the control units 14 to the position corresponding to the minimum value of the radius of downstream roller 8, which assumes the value r.

Gearings 26 are mounted to the axles XX and YY and thus permit the adjustment of the rotational speed of upstream roller 7 in relation to the rotational speed of the downstream roller 8.

In FIG. 7A, there is a radius R upstream and a radius r downstream, the drawing ratio E thus being at a minimum.

By contrast, by rocking the fork 21 in the opposite direction (FIG. 7B), a radius r is obtained on the upstream roller 7 and a radius R on the downstream roller 8, the drawing ratio E thus being at a maximum.

The pivoting of fork 21 is controlled by a control unit 27. As shown, this unit can be a hydraulic, pneumatic or electric actuating cylinder or a manual nut-and-bolt system. Thus, there corresponds to each position of control unit 27 for controlling the fork 21 a value of the radii of rollers 7 and 8, i.e., a value of the drawing coefficient. Positions of control unit 27 can be controlled by electrical means on the basis of predetermined or programmed set values.

In another embodiment (FIGS. 8A and 8B) of the apparatus of the invention, gearing 26 is placed on the side of control units 14. Ramps 17 are integral with a shaft 18 concentrically mounted to the rotating axle XX. The axle XX has a stop 29 mounted on one end thereof a spring 24 is seated on one end against the stop 29. Fork 21, as it swivels, compresses the spring 24 which in turn brings about the displacement of hubs 15 axially in the direction of arrow F4, i.e., in the direction of movement of fork 21. Ramps 27 in turn slide in grooves 18, which causes the downstream cylinder 7 to expand. By contrast, upstream cylinder 8 is not compressed.

Preferably, portions 11 have on the outer surface an adhesion-promoting lining.

FIGS. 5 and 6 show other forms of construction of the rollers. On the left side of each figure, there is provided a half-roller 30 with a smaller radius and on the right side a half-roller 31 with a larger radius.

In FIG. 5, half-roller 30, like half-roller 31, consists of portions 32 that are integral with radial compressible elements 33. Preferably, they are made from elastomeric material. These radial elements 33 are located between radial fixed partitions 34 and radial movable partitions 35 that are integral with a shaft 36 capable of sliding axially. When shaft 36 is moved axially, movable partitions 35 move closer to fixed partitions 34, the elastomeric element is compressed axially and deformed radially as it urges portion 32 radially outwardly. The radius of the half-roller thus increases. When movable partitions 35 are moved away from fixed partitions 34, the elastomeric element 33 returns to its initial form. Preferably, the elastomeric elements are placed at each end of portions 11. In FIG. 6, portions 11 are displaced by means of a hydraulic device. The displacement of piston shaft 37 brings about the displacement of support 38 of portion 11, with the hydraulic liquid transmitting the pressure between piston shaft 37 and support 38.

The hydraulic liquid is located within the chamber formed by a hollow shaft 39, with shaft 37 sliding axially and support 38 sliding radially.

In certain applications, the devices described hereinabove, particularly in FIGS. 1, 5, 6, 7A-7D, 8A and 8B, have the disadvantage that the portions strike against the tensely stetched film, thereby producing a noise due to the repeated blows of the portions or metal bars on the taut film.

Furthermore, the drawn film undergoes a transverse shrinkage, that is to say, the final width of the drawn film is smaller than its initial length. This is a drawback for obtaining the good quality of banderoling required in the packing industry.

Moreover, the portions forming the cylinders of revolution, which consist of metal bars, can cause the taut film to be torn because of the metal edges that can be more or less cutting.

In addition, the portions or metal drawing bars are returned by return springs whose purpose is to give a smaller radius to the drawing cylinder, if the latter was previously provided with a larger radius. Now, these return springs are placed within the drawing cylinders made up of the various portions, and the practical construction of these devices is complex.

Therefore, the invention is also directed toward remedying these drawbacks by providing the rollers with external elastic means for returning the portions to the axis of revolution.

Preferably, these external return devices consist of at least one elastic band placed around and within the portions.

For example, the elastic bands are circular rings that are spaced a distance from one another. Preferably, the rings are made integral with the portions, e.g., by adhesive bonding.

The fact that external elastic return means are placed on the portions permits elimination of the return springs which cause the decrease of the cylinder radius. Moreover, the elastic bands considerably reduce the noise created by the portions or metal bars striking against the taut film. In addition, the elastic devices also constitute means for protecting the film, because they cover the cutting edges of the portions or metal bars, thus preventing the drawn film from contacting these portions or metal bars.

Roller 40 depicted in FIG. 9 may either be a roller of the type shown at 3 of FIG. 1 or of the type illustrated at 7 and 8 of FIGS. 7A-7D, 8A-8B, or 30, 31 depicted in FIGS. 5 and 6.

The roller 40 includes a plurality of longitudinal portions 41₁, 41₂, 41_(N), which form the cylindrical surface of roller 40.

According to the invention, roller 40 is provided with external means 42 for returning the portions 41 to the X--X axis.

Therefore, when portions 41₁, 41₂, 41_(N) are moved with the aid of the separating means described hereinabove in order to increase the radius R₀ or radius r₁, the external elastic devices 42 return the portions 41₁, 41₂, 41_(N) to the X--X axis of the cylinder of revolution 40.

These external elastic means 42 consist of an elastic band placed around and outside of portions 41₁, 41₂, 41_(N).

According to a first embodiment of the invention shown in FIG. 9, the elastic band is made up of several circular rings 43₁, 43₂, 43_(N) of axles XX spaced a distance from one another. These circular rings with, e.g., a height h, have a radius r which is substantially equal to the radius r of the drawing roller, i.e., radius r of bands 43_(N) is slightly smaller than the smallest radius the roller can have. Thus, bands 43₁, 43₂, 43_(N) keep portions 41₁, 41₂, 41_(N) substantially contiguous with each other these bands 43₁, 43₂, 43_(N) are not drawn.

When portions 41₁, 41_(N) are subjected to a radial displacement so as to separate portions 41₁, 41₂, 41_(N) from the axis of revolution XX of roller 40, the elastic bands 43₁, 43₂, 43_(N) are exposed to a radial force, indicated by the arrow F₅, which causes the bands to have a radius that is larger than their initial radius, substantially equal to the radius desired for the drawing roller. The bands are thus subjected to a force F₅ that draws them.

When the means for separating portions 41₁ -41_(N) are inactive, the bands are no longer subjected to force F₅ and, since they are elastic, they have a tendency to return to their initial shape and to take back their initial radius r and, thereby subjecting portions 41₁, 41₂, and 41_(N) to a force which is opposite to force F₅ in order to return them to their original position.

Preferably, circular rings 43₁, 43₂, 43_(N) are spaced a distance e from one another.

Preferably, the distance e between two successive rings 43₁, 43₂ is a few millimeters, e.g., more particularly about 2 to 3 mm.

FIG. 10 shows an enlarged view of two rings 43₁, 43₂ and film 1 which rests on these two rings. As can be seen, film 1 rests on rings 43₁ and 43₂, whereas it does not rest on the portions 41₁ -41₇ themselves between rings 43₁, 43₂, that is, when the film lies in the space formed between rings 43₁ and 43₂.

FIG. 11 depicts another embodiment of the invention. The band forming the elastic means 42 is composed of 2 parts 44 and 45. The first part 44 is a band which is helically wound in one direction, while the second part 45 is another band which is helically wound in the opposite direction.

The first part 44 is wound in the direction opposite to the direction of rotation of roller 40, as indicated by the arrow in FIG. 11, while the second upper part 45 is wound in the direction of rotation of roller 40.

Likewise, the spires of bands 44 and 45 are not contiguous and they are spaced apart by a distance e. Preferably, this distance e measures a few millimeters and, more preferably, approximately 2 to 3 mm.

Therefore, the helical spires are not opposed and are symmetrically distributed relative to the longitudinal axis Z--Z of the film which is drawn. Thus, the direction of winding of the helices of parts 44 and 45 is such that the film is exposed to a component of reaction of the helical spires on the film, said component being directed to the external edge 100 and 110 of drawn film 1 (FIG. 12). Consequently, film 1 is subjected to transverse drawing in the direction of the components of reaction of the helical turns on the film (direction and sense of arrows r) and the film is then not subjected to transverse shrinkage as it is being drawn, or at least it is subjected to less transverse shrinkage than when it is drawn by rollers that do not have an elastic helical band. The plane of each spire is oriented at an acute angle α with respect to the direction of displacement v_(n) of the drawn film. Preferably, α is less than 46°.

Furthermore, according to the invention, an advantage of the elastic means 45 is that the portions 41₁, 41_(N), which are often metal bars, do not strike the film, since the elastic means are situated between the film and these metal bars. This reduces the noise produced by the apparatus.

In addition, since the film does not rest directly on portions 41₁, 41_(N), it is less likely to be torn by their edges.

Finally, it is preferable that the circular rings 44₁, 43₂, 43_(N) or the helically wound bands 41, 45 be integral with portions 41₁, 41_(N), e.g., that they be adhesively-bonded.

The rings and the helical bands are preferably made of a vulcanized sheet of rubber. 

We claim:
 1. An apparatus for stretching a deformable film, comprising:first means for drawing a deformable film, the first means including a first roller and a second roller, each roller including a plurality of longitudinally extending surface members, the surface members forming a substantially cylindrical support surface defined by a radius on the respective roller for supporting the deformable film, each surface member thus corresponding to a respective film section of the deformable film; a first rotating axle and a second rotating axle supported substantially parallel to said first rotating axle, said first axle rotatably supporting said first roller and said second axle rotatably supporting said second roller, each of said axles extending in the longitudinal direction of said surface members; second means coupled to said surface members for driving said surface members in a radial direction substantially perpendicular to the axial direction of said respective axle; third means coupled to said rotating axles for rotatably driving said axles and thus said surface members; and a control unit coupled to said second means to control the movement of said surface members in said radial directions and thus adjust the diameters of said cylindrical support surfaces, said control unit being adapted to adjust the diameter of said support surface of said first roller relative to the diameter of said support surface of said second roller to obtain differential speeds between the film sections supported by said first roller relative to the film sections supported by said second roller to stretch the deformable film.
 2. The apparatus as set forth in claim 1, whereinthe drawing ratio (E), which is the ratio of the tangential speed V₁ at a point of the film downstream, following drawing, to the tangential speed V₀ at a point of the film upstream, prior to drawing, is proportional to the ratio of the radius R₁ of said cylindrical support surface of said first roller to the radius R₀ of said cylindrical support surface of said second roller.
 3. The apparatus as set forth in claim 2, whereinsaid control unit varies the drawing ratio (E) by simultaneously varying said radius R₁ and said radius R₀ between two values r and R.
 4. The apparatus as set forth in claim 3, whereinsaid drawing ratio varies approximately from 0 to 100%, and said radii R₀ and R₁ vary between r=±80 mm and R=±113 mm.
 5. The apparatus as set forth in claim 3, whereinsaid drawing ratio varies approximately between 0 and 200%, and said radii R₀ and R₁ vary from r=±70 mm and R=±123 mm.
 6. The apparatus as set forth in claim 3, whereinthe limits within which said drawing ratio (E) varies are adjustable by adjusting the ratio of the rotational speeds of said first and second rollers.
 7. An apparatus as defined in claim 1, whereinsaid second means includes a plurality of guide members coupled to said surface members of said first and second rollers; and a plurality of hubs coupled to each of said first and second rotating axles and to said control unit, each of said hubs defining at least one groove therein for slidably receiving a respective guide member therein, each of said hubs being adapted to slide relative to said respective axle in substantially the axial direction thereof in response to said control unit to, in turn, drive said guide member and, thus, said respective surface member in said radial direction to adjust the diameter of said respective cylindrical support surface.
 8. An apparatus as defined in claim 7, wherein said control unit includes:a fork member pivotally supported about an axis substantially perpendicular to the axial direction of said first and second axles; a first rim member coupled to a first end of said fork member and to said hubs of said first axle, said first rim member being adapted to drive said hubs relative to said first axle in response to said fork member being pivoted about its axis; and a second rim member coupled to a second end of said fork member and to said hubs of said second axle, said second rim member thus being adapted to simultaneously drive said hubs relative to said second axle, in response to said fork member being pivoted about its axis, in the opposite direction that the first end of said fork member drives said hubs of said first axle to, in turn, simultaneously adjust the diameter of said support surface of said second roller relative to said support surface of said first roller. 